Systems for computing and controlling the generation of interconnected sources



Dec. 23, 1958 Original Filed March 26, 1953 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES 13 Sheets-Sheet 1 f O F 1 AREA A AREA A 29A 1 MASTER CONTROL REGULATlON REQUIREMENT FOR J/ 30A AREA A$S|5T uurrs M IOA I2Al FREQ.

A5 an IBM 112,1: I4AI 4 4 I5Al LDO 5111. Al ,2OA| 5TN Al M REGULATKON REQUIREMENT 7 5TH. A4 H 2mm) W 211 7 2l(3Al) 5: :1 6: z: 2 IAI) 22mm) 22mm) 2 3 3| FREQ. "IF

Ble5

25(IAI) 260A" ,umTlAl uun' 53: 1:. g -ZKIAI) mumzmsN r/ ZTUAI) ZBUAU FUSIHON GOV GOV. MOTO R Dec. 23, 1958 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION 0F INTERCONNECTED SOURCES Original Filed March 26. 1953 13 Sheets-Sheet 2 wmnvg "HAVE m; mm

15 Sheets-Sheet 3 Dec. 23, 1958 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 u n 2.5 u n M U 20mm ismsmw |\|I lllllltlllll Dec. 23,

AREA 5 REGULA'HON N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 SUSTAIN ED RE5PON$E AREA E5 REQUIREMENT IOB } sTN REGULAHON 6TH. B

REQUIREMENT ZIUBI) UNIT I B l BASE FUN? TO 3Bl TBZII GOV- 60V.

23(IBI) 27(IBI) UNlT |B\ REQUIREMENT Umr 1B4 REQMREMENT CONTROLLER Gov. ov.

Pnsmou MOTOR 15 Sheets-Sheet 4 Fig.

AREA ASSKST STN B4- REQLHREMENT Dec. 23, 1958 N. COHN 2,866,102

SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 15 Sheets-Sheet 5 Fllllllllllllllllllll v a umooJ w g --L .L X. an a. a. UN... V

N. COHN 2,866,102 SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 13 Sheets-Sheet 6 F l I l I I l I I Dec. 23, 1958 5 2km Q.

9 Ri s Four Dec. 23, 1958 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION 0F INTERCONNECTED SOURCES Original Filed March 26, 1953 Fig.5

13 Sheets-Sheet '7 AREA c Q; REQUIREMENT 188 IQC v IZCI 2l2Cl m 3?. 2*; 7

S .5 Q5 o a v 0 I'TCI 205 on 20503 lsbl N I4Cl LDO I5CI f -:E

sm; Q 92(01) ISCI 206(CI) CI STNCI 5TN. R u S REGULAT'ON REQUIREMENT R a Cl 2' ZZKICI) w ZZICSCI) zeucn 221(200 UNITICI 7. I if}: u DIAS 24(IGD-Emgi 022;. 250C 2300i) 28 UNlT |c\ zfi r CONTROLLER ASSIST V GOV. To PDSH'IQN GOV.

Dec. 23, 1958 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 13 Sheets-Sheet 8 mu ESE,

u 5oz". 205k 50mm uu M||1 lllll E U ww 13 Sheets-Sheet 9 Dec. 23, 1958 co SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 Cl) J COMEE outing Fvwm u z.rw -1 L W mm :QETWMWE Dec. 23, 1958 N. COHN 2,866,102

SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26. 1953 15 Sheets-Sheet 10 E I $U$TAINED RESPONSE J l a AREA D AREA 0 I-AREA AS5151 REGULATION REQUIREMENT E I Q9 I I MASTER I IZDS 202 CONTROLLE+3OD .3 Ii? 7,] I? A lzol |3D3 I302 I5DI f v g-L,I9OIDD [E00 STN DI STN. DI AREA REGULATION REQUIREMENT REQT.

lODl

ZODI |9D i v H 22|(2Dl) 2'60) ZKZDD ZIIIDI) ZZIIIDI) {3'27 a] IYS'FZT ZZZIIDI) q) 225(IDI) 2300') 222(31):) 222mm gags I 1 24m) 224mm). 5 223000 I F I I I 233M239 2280 0 I I m m I i COMBINED ZTIIDI) CONTROLLER J REQUIREMENT l susTAmED J I fizASSIST I 229 I I 230 l Gov-MOW l 227(IDI) I E 1 Ta um: IDI

Dec. 23,- 1958 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 13 Sheets-Sheet 11 Na .5 51km Zw-v 8x55. Pump. or m mo 2.5 Ens Zouu B 2.5 A .0 zrh n ow $039.. I] I I I I ni swm EOE WMM MWU E5. 53 I L I SK: 53.. EN

ll L nm g MOE mom- 0mm Dec. 23, 1958 N. COHN SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Original Filed March 26, 1953 15 Sheets-Sheet 12 mmN I u I I I I Q u M 55mm 53mm n fiw L. 8:56 m w l l N! qwymkwah :2 .22:

6m q l Now oom EEO. 5:6 !5 s 52% w uu ONm kwzivwamwrwflw .kOmk wx Punk .9 :2: "Q 1 1 V m 1W m m on 2&3 I I I I I l l l l l l 1 o 2 mm SK Dec. 23, 1958 Original Filed March 26, 1953 Source Gen Area Reqt.

(Plus) N. COHN 2,866,102 SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES 15 Sheets-Sheet 13 (Mmus) Need for P Decreased Gan Need for Increased Gen Increase GI G2 Source Gen.

Gb Gt Total Area Gfe' Total Area Gen.

Gen. w c 5 z I 0 U o-- V y- 90 g T V N E PW" 3. 6n I Increq3e- Q B\ I Increase-'- Freq. i i f 62 Source Gen.

AF 1T- i N I 3 1 11 I. 6b i i T \MS w N Ste w u g 3 M Un d States SYSTEMS FOR COMPUTING AND CONTROLLING THE GENERATION OF INTERCONNECTED SOURCES Nathan Cohn, Jenkintown, Pa., assignor to Leeds and Northrup Company, Philadelphia, Pa., a corporation of Pennsylvania Continuation of application Serial No. 344,838, March 26, 1953. This application September 11, 1956, Serial No. 609,111

45 Claims. (Cl. 30757) This invention relates to the computation and control of the generation of stations and units of a generating area which is interconnected for interchange of power with one or more other areas of a distribution network. For brevity, the term generating source as hereinafter used is generic to stations or units.

In various of its features, the present invention is generically similar to that disclosed and claimed in my copending application Serial No. 344,838 upon which was issued Letters Patent No. 2,773,994. In that application, there are disclosed arrangements for computing and controlling the generation of stations and units of a local area so that they participate in accordance with predetermined programing in the total prevailing generation 'of the area and in the generation changes required of the area to correct deviations from a scheduled interchange of power;

However, all of the arrangements herein disclosed differ therefrom in that the computation of station and unit requirements involve assigned frequency-bias factors which compensate in the computations or exclude therefrom, the effect of normal governor response to system frequency changes. Thus both the station and unit requirement recorders or controllers remain at zero despite governor responses to remote load changes and depart from zero only for local load changes.

When, as in all of the arrangements herein disclosed, the computation of station (or unit) requirement involves a feedback signal related to station (or unit) generation, the novel bias introduced inaccordance with the present invention will include at least one factor: i. e., the frequency-bias which corresponds with either the natural or the desired frequency response of the station (or unit). When, as in some arrangements herein disclosed, the computation of station (or unit) requirement additionally involves a signal related to total area (or station) generation, then the novel bias should include an additional factor, i. e., a frequency-bias which is a preset percent of the area (or station) frequency-bias, the percentage numerically corresponding with the assigned percent participation in the area (or station) regulation of the particular stations (or unit).

The introduction of such factors at station or unit level affords a more precise computation of station and unit requirements upon occurrence of remote or local load changes because of compensation in the computation for the effect of the natural governing responses of the individual stations and units. Thus, when such computations are used for mandatory control as distinguished from permissive control, as later more fully discussed, with systems involving feedback related to station or unit output, the control has the advantageous characteristic of not opposing the natural governing response of the station or unit but indeed may selectively predetermine the governing characteristic of the station or unit to modify or replace that of the usual speed-governor.

For a more complete understanding of the invention,

ill

, 2,866,102 Patented Dec. 23,-. 1,9?8

reference is made to the accompanying drawings, in

which:

Fig. 1 is a block diagram of a system for controlling the generation of the stations and units of a generating area in accordance with the invention;

Figs. 2A and 2B jointly disclose a particular embodiment of the system of Fig. 1; Figs 2A and 2B respectively showing the control circuit components disposed at the load dispatchers oflice of the area and at one of the stations of the area;

' Fig. 3 is a block diagram of a second system for controlling the generation of the stations and units of an area in accordance with the invention;

Figs. 4A and 4B jointly disclosed a particular embodiment of the system of Fig. 3; Figs. 4A and 4B respectively showing the control circuit components disposed at the load dispatchers oflice and at one of the stations of the area; p

Fig. 5 is a block diagram of a third system for controlling the generation of the stations and units of an area in accordance with the invention;

Figs. 6A and 6B jointly disclose a particular embodiment of the system of Fig. 5; Figs. 6A and 6B respectively showing the control circuit components disposed at the load dispatchers ofiice and at one of the stations of the area;

Fig. 7 is a block diagram of a fourth system for controlling the generation of the stations and units of an area in accordance with the invention;

Figs. 8A and 8B jointly disclose a particular embodiment of the system of Fig. 7; Figs. 8A and 8B respectively showing the control circuit components disposed at the load dispatchers office of the area and at one of the stations of the area; and

Figs. 9A-9D are explanatory figures referred to in I discussion of the computer and control systems of preceding figures.

In simplified block diagram form, Fig. 1 illustrates the principal components and interconnections of a control system for stations and units of area A having tieline connections to one or more other areas of a powerdistributing system. The block 10A is generically illustrative of a network or device for producing a signal representative of the area requirement which may be defined as the difference between the scheduled and actual net interchange of power at the existing frequency between the local generating area A and the other or foreign generating areas; The scheduled net interchange at various frequencies involves, as later discussed, an area-bias factor usually set to match the natural governing characteristic of the area so that the area-requirement remains on zero for remote load changes. The block 11A is generically illustrative of a network or device for producing a signal representative of the area regulation which may be defined as the difference between the summation of the generations of the stations of area A and the summation of the basepoint generation setting of those stations. The area regulation is related to total area generation and is equal to it when basepoint setters are omitted or set to zero. As more fully discussed in my aforesaid applicapation setter 12A1 is compared by a network or device 13A1 with the resultant of signals respectively corresponding with the actual generation of station A1 as pro- Q3 duced by device 14A1; with the preset basepoint of station A1 as produced by device A1; with the preset frequency-bias for station A1 as produced by device 16A1; and with a percentage of area frequency-bias as produced by device 17A1 and corresponding with the setting of participation setter 12A1. The output signal of comparator HA1 is representative of the station requirement for station Al, i. e., the change in generation required of station A1 to meet its proportionate share of the total prevailing generation of the area plus its share of the generation required of the area to meet its schedule.

Signals respectively representative of the station requirements for the other stations A2, A3 of area A are similarly derived from the participation setters 12A2, 12A3, comparators 13A2, 13A3 and associated devices (not shown) corresponding with devices 14A1-l7AL The station-requirement signals may be utilize-d, as in manner later specifically described, automatically to control the generation of the respective stations Al-AS.

The significance of the addition of the station frequency-bias factor and a percentage of the area frequency-bias factor in the computation of station requirement can perhaps be best illustrated by a specific numerical example. Without these factors, the station requirement (AG) may be expressed as B==station basepoint G=station generation N area regulation T=area requirement P=station percent participation setting It is assumed, as initial conditions, that the station A1 is operating at its basepoint setting of 50 megawatts, that its participation setting is 40%, and that the area regulation and area requirement are both zero. The initial station requirement is also zero as will be seen by substituting these values in Equation 1.

It is now assumed that the area frequency-bias is set to 100 megawatts per 0.1 cycle (the natural governing characteristic of the area), that the prevailing natural governing characteristic of station A1 is 25 megawatts per 0.1 cycle, and that, due to a sudden load change in a foreign area, the frequency drops by 0.1 cycle. Because of the frequency drop, area A by governing action picks up 100 megawatts, i. e., area regulation now reads 100. Because the area bias setting matches the natural governing characteristic of' the area, the area requirement remains at zero. The generation of station A1 increases to 75 megawatts because of its governing response to the frequency drop. By substitution in Equation 1, the computed station requirement for station A1 is shown below to be 15 megawatts positive:

Thus although station A1 has, due to governing action, taken on a 25 megawatt load due to load change in the foreign area, the computed station requirement indicates it should pick up an additional 15 megawatts contrary to the desirable objective that the generation changes in the local area should be limited, upon occurrence of load changes in a remote area, to the natural governing action. In the foregoing example, wherein the percent participation for station All was higher than the ratio of the station governing characteristic to the area governing characteristic, the computed station requirement was positive, i. e., calling for station generation in addition to governor response. Had the percent participation been selected to be smaller than such ratio, the computed station requirement would be negative,

45. i. e., in sense opposing the governing contribution of the station. For example, under the same conditions and assumptions as above except that the participation setting for station A1 is 10%, the computed station requirement as shown below is 15 megawatts negative:

When the computed station requirement is utiized for mandatory control of station generation (contrcl action initiated upon. existence of station requirement and persisting until station requirement is zero), the generation changes demanded by the computation of Equations 1A, 1B are not desirable and result in unnecessary and un economic generation shifts. Neither matches governing response, and both demand further control, in one case forcing generation beyond governor response and in the other case rejecting the governing response, wholly or in part.

With the frequency-bias factors added, as in Fig. 1, this situation is corrected. Now the computed station requirement (AG) may be expressed as K=station bias per one-tenth cycle,

L=area bias per one-tenth cycle, and

AF =frequency deviation in tenths cycle (minus for frequency drop).

Assuming the same initial conditions as before, and with the station-bias factor set at 25 megawatts per onetenth cycle to match its natural governing characteristic, the same frequency drop (0.1 cycle) due to change of load in a foreign area gives, as shown below, for a participation setting of 40% a computed station requirement of zero.

Similarly, with a participation setting of 10%, the computed station requirement is also zero:

From the foregoing, it will be understood that with such introduction of frequency-bias factors for the station, the change in station generation resulting from response of the speed governors of the generating units of that station to a remote load change can persist without causing a station-requirement demanding additional control action. Otherwise stated, the inherent action of the local governors in helping to check a frequency change is not opposed or enhanced by a control based on station requirement so computed.

In actual practice, the inherent governing characteris tic of a station may be variable and hence cannot be matched throughout the generation range of the station by a preset station frequency-bias. This, however, creates no operating difficulty or limitation because then the control action based on Equation 2 to reduce AG to zero corrects any mismatch, imposing upon the station a desired frequency-responsive characteristic which is defined by the setting of station frequency-bias. in fact, the unit speed-governors of a station may be set with a steep droop, or otherwise set to be unresponsive to normal frequency changes, and retained only for emergency overspeed protection; in such case, the control based on Equation 2 and with generation adjusted until AG is zero, effectively assigns to the station a preselected frequencygcverning characteristic effective over the full operating range and free of the usual disadvantages and vagaries oi speed governors including deadband, slpggishness, in=

sensitivity, sharpchanges of incremental slope, and general wear and change of calibration with time, temperature and other variables.

The station frequency-bias may thus be set to a value other than the inherent frequency response of the station,

The retention of the station frequency-bias factor K provides the desired frequency-response characteristic of the station. In Equation 2, area bias, L, may be set to zero in which case also the frequency bias term reduces to AFK.

The computed station requirements as represented by the outputs from comparators 13A113A3 are respec tively transmitted to the corresponding stations of the area and are there utilized for control of generating units of the respective stations. Specifically and as schematically illustrated in Fig. 1, the requirement signal for station A1 is utilized to control the generation of units 1A1-3A1 of that station so that they participate to predetermined programming in the generation change required of station A1 to meet its share of the area requirement.

At station A1, its computed requirement signal is reproduced as the output signal of a suitable network or device represented by block 19A1. The block 20A1 is generically representative of a network or device for producing a signal representation of station regulation which may be defined as the difference between the summation of the generation of the units of station A1 and the summation of the basepoint settings of those units. The station regulation is related to total station generation and is equal to it when the unit basepoint setters are omitted or set to zero. The algebraic summation of these two signals (station-requirement and station-regulation) provides, as more fully discussed in my aforesaid application, a reference signal corresponding with the total generation required of the station to supply its programmed share of the total area generation required to maintain the area on its schedule.

By the participation setters 21(1A1)21(3A1), selected fractions or percentages of this reference signal are derived for control of the corresponding units 1A13A1 of station A1. The output signal of participation setter 21(1A1) is compared by a network or device 22(1A1) with the resultant of signals respectively corresponding with the actual generation of unit 1A1, the preset basepoint generation of unit 1A1, the preset frequency-bias for unit 1A1, and a percent of the station frequency-bias corresponding with the setting of the station frequencybias setter 16A1. These latter signals are respectively produced by the devices or networks 2326 of the corresponding generator unit 1A1. The output signal of comparator 22(1A1) is representative of the unit requirement for generating unit 1A1: i. e., the change in generation required of unit-1A1 to meet its programmed share of station Als total generation and generation requirement.

Signals respectively representative of the unit requirements for each of the other units 2A1--3A1 of station A1 are similarly derived from the participation setters 21(TA1), 21(3A1), comparators 22(2A1) and 22(3A1).

The respective unit-requirement signals may be reproduced for automatic control of the generation of the corresponding units as by control of the input valves or gates of vapor or hydraulic prime movers respectively or by control of the rate of vapor generation of their supply sources including nuclear'powered sources. In theparticular arrangement schematically illustrated in Fig. 1, the governor motor controller 28(1A1) for unit 1A1 is responsive to the unit-requirement signal reproduced by device 27(1A1).

By addition of and proper setting of the unit frequencybias factor and of the percent station-bias factor in the computation'of a unit requirement, the change in generation of the unit resulting from response of its speed governor to a remote load change can persist without appearing as a unit requirement demanding corrective control action. The inherent action of the governor in responding to a frequency change caused by a remote load change is not opposed by a control based on the computed unit requirement. For the reasons above discussed ill connection with matching of station-frequency bias to station-frequency characteristic, it may not be possible to match the unit-frequency bias to the natural governing characteristic of the unit throughout the generation range of the unit. In this case also, the control action corrects the mismatch.

The computed unit requirement AG for the arrangement disclosed in Fig. 1 may be expressed G'=unit generation P'=unit percent participation N'=station regulation AG=station requirement (see Equation 2) AF=frequency deviation in tenths cycle (minus for drop in frequency) K'=unit bias per one-tenth cycle K=station bias per one-tenth cycle With a control based on Equation 4 for adjustment of unit generation until AG becomes zero and with the unit frequency-bias set to a value different from the natural governor response, the unit frequency-bias will be the determining factor in establishing the frequency response of the generating unit.

When, as later discussed, the computation of unit requirement for mandatory control involves area requirement but not area or station regulation then the percent station-frequency-bias factor may be omitted. The retention of the unit frequency-bias factor then provides the desired frequency response characteristic of the unit.

In the system of Fig. 1 as thus far described, i. e., the portion to the left of line C--C, the control of the generating stations provides for each of them on occurrence of a local load change, an initial generation assignment (from an area requirement effect) which is identical to its sustained requirement (from area regulation effect). This is because for each station there is a common percentage taken for both effects by the respective participation setters 12A112A3. As a result, the generation changes are assigned to the stations which are to retain them so long as the local load remains at the new value. Similarly, at the station, since for each unit there is takena common percentage of the station regulation and station requirement effects, the initial and sustained generation assignments to individual units are equal. As a result, the generation changes are assigned to the units which retain them so long as the local load remains at the new value. The stations and units controlled as above described are hereinafter termed sustained-response" stations and units. Sustained response control sutfices so long as the generating sources are capable of changing their generation at a rate at least equal to the rate of change of customer demand. If such capability is exceeded and it is desired not to depart from the area tieline interchange schedule, there is provided temporary regulating assistance, hereinafter termed area-assist,

'way of providing an area assist action by station A4 having generating units 1A4-3A4. With switch 29A closed, area-assist units 1A43A4 are directly controlled from master controller 30A through their respective governor controllers 31. Throughout the period for which an area requirement exits, the master controller produces Raise or Lower pulses which for that period are effective progressively to change the governor settings of the area-assist units in corrective sense. This is in contrast to the control of the sustained response units in which, as above explained, the change in governor setting of each unit is terminated when its own unit requirement (AG) is zero even though some area requirement may still exist.

As schematically illustrated in Fig. 1, the basepoint generation and the actual generation of area-assist station A4 are introduced, with switch 29B closed, by devices 14A4 and 15A4 into computer 11A which determines the regulation of area A. Thus, the changes in generation assumed by the area assist station A4 above or below its basepoint setting, are ultimately transferred to the sustained response stations because the latter are subiect to mandatory control continuing until AG of each of the sustained response units is zero.

For convenience, the switches 29A, 29B are ganged. With these switches closed, the system of Fig. 1 includes the above-described area-assist action of station A4.

Figs. ZA-ZB illustrate, as combined. a partcular example of the computer control system of Fig. 1 as utilized for full automatic control of generating stations and units of an area. Fig. 2A illustrates the networks and devices disposed at the load-dispatchers office of an area for determining the various station requirements and for producing signals transmitted to the various stations to demand change of their generations. Fig. 2B illustrates the networks and devices utilized at one of the stations of the area for determining the requirements of its sustained response units and for controlling them, and those utilized at another of the stations to provide for its area-assist control.

In the following descriptions, whenever reference is made to the positioning of a slidewire or of a slidewire contact it will be understood that either the contact or the slidewire may be the adjustable element.

Referring to Fig. 2A, the network 10 for producing a signal voltage representative of an existing area requirement is a split potentiometer or bridge including a slide- I wire 35, fixed resistors 36 and a suitable supply source. The position of contact 37 relative to slidewire 35 is ad usted by rebalancing device 38 of a computer network 39A so that the output of network 10 corresponds with the existing requirement of area A as computed by network 39A.

The computer network 39A includes three component networks 40, 41, 42 having individual su ply sources and respectively including the rebalancing slidewire 43 whose contact 44 is adjustable by responsive device 33; the slide- "mon current supply source. The ultimate source may be of the alternating or direct-current type.

In all cases, the supply voltages of the component networks of a computer network must be individually fixed or all vary together in the same ratio. a

The position ng of contact 49 of slidewire 48 of network 42 can-be effected by any arrangement which total-:

izes the net-interchange between the area A and'the rest of the system. For example, contact 49 may be coupled to the exhibiting element 62 of the net-interchange meter or recorder 50A responsive to the output of the summation network exemplified by block 63A and including slidewires respectively positioned by tie-line meters or recorders 64 effectively connected through telemetric links to tie-line interchange points of the area.

The component network 42 also includes a slidewire 51 whose contact 52 is manually set to a position corresponding with the scheduled net-interchange of power between area A and the rest of the power-distribution system. Thus, when the actual net-interchange is at the value scheduled for normal system frequency, the output voltage of network 42 is zero. If the actual interchange departs from this value, the output voltage of network 42, because of the resulting displacement of contact 49, corresponds in sense and magnitude with such deviation.

The component network 41 additionally includes a slidewire 53 whose contact 54 is manually set to a position corresponding with the normal system frequency agreed upon. Thus, when the actual system frequency is at normal value, the output signal voltage of network 41 is zero. If the system frequency departs from normal, the output voltage of network 41, because of the resulting displacement of contact 46, corresponds in sense and magnitude with such frequency deviation. To preset the extent to which the scheduled interchange varies with actual system frequency (i. e., area-frequency bias) the network 41 additionally includes the fixed resistors 55, 55 in series between the supply source of the network and slidewires 45, 53; and the slidewire 56 whose contact 57 is manually set in accordance with the agreed frequency-bias for the area. The setting of contact 57 therefore determines the extent to which the output of network 41 changes for any given deviation from the preset normal frequency. In the foregoing, it is assumed that switch 32 is closed to short-circuit slidewire 33 whose purpose is later discussed.

The output voltages of component networks 41, 42 are combined so that the resultant is at all times representative of the area requirement. When this resultant is not equal and opposite to the output of the third component network 40, the responsive device 38 adjusts the Contact 44 of slidewire 43 until balance of the computer network 39A is obtained. Thus, the relative position of contact 44 and its slidewire 43 corresponds with an existing area requirement.

Concurrently with its rebalancing of computer network 39A, the responsive device 38 also correspondingly positions the slidewire contact 37 of network 10, the exhibiting element 59 of the area-requirement meter 60A and the contact 61 of master controller 30A.

From the foregoing. it will be understood that the output voltage of network 10 at all times corresponds with the existing area requirement (T, Equation 2) of area A and involves tie-line interchange, frequency and frequency-bias factors. It may include additional factors such as disclosed in my copending application S. N.

Network 65A, which includes network 10 as one of its components, also includes network 11 whose output voltage is representative of area regulation. Network 11 is a split potentiometer or bridge including fixed resistors, 66, 66 and a slidewire 67 whose contact 68 is positioned to correspond with the computed difference between the summation of the basepoint settings of stations A1A3 of area A and the summation of the actual generations of those stations. With switches 29B, 29B closed, the computed difference additionally includes the basepoint setting and the actual generation of station A4.

For automatic adjustment of contact 68, it is coupled to the rebalancing device 69 of computer network 70A includingv a series of network pairs 71,72 in number corresponding withthe stations of the area. Each net- 'work 71 includes a slidewire 74 whose contact 75 is manually preset by the associated one of the base-load setters A1-15A4 for the desired base-load of the corresponding station. Each network 72 includes a slidewire 76 whose contact 77 is positioned, in accordance with the actual generation of the corresponding station. For station Al, the actuator 14A1 for contact 77 of corresponding network 72 responds to signals received by telemetric receiver 78A1. As indicated, networks 71, 72 are connected in series in computer network A so that their resultant output is the summation of the differences between the basepoint settings and actual generations of the controlled stations, i. e., the resultant output corresponds with area regulation. 1

In computer network 70A the component network 7 for balancing this resultant of the outputs of network pairs 71, 72 is a split potentiometer or bridge including fixed resistors 79, 79 and a slidewire 80 whose contact 81 is adjustable by the unbalance responsive device 69. Since contact 68 of slidewire 67 of network 11 is also repositioned by the responsive device 69, the output of network 11 of computer network 65A corresponds with area regulation (N, Equation 2) The outputs of component networks 10 and 11 are combined in network 65A to provide a reference signal [(N-l-T); Equation 2] of sense and magnitude corresponding with the algebraic sum of area requirement and area regulation. Pre-selected percentages of this signal are allocated to the different sustained-response stations A1A3 predetermine their participation in the total prevailing generation of the area plus the change in generation required of the area to meet the area schedule.

Specifically in Fig. 2A, the participation slidewires 12A1-12A3, in number corresponding with the sustainedresponse stations of area A, are traversed by a reference current whose sense and magnitude are determined by the algebraic sum of the outputs of component networks 10, 11. The contacts 82 of these slidewires are respectively manually preset in accordance with the desired percentage participations (P, Equation 2) of the corresponding stations. The voltages produced across the selected portions of these station-participation slidewires are respectively introduced into computer networks 85A185A3 for determining the respective station requirements and for producing signals transmitted to the individual stations for control of their respective generations.

The station requirement network 85A1 for station A1 is shown and now described. Similar computer networks 85A2, 85A3 are used for the other sustained-response stations of area A. In addition to the station-participation slidewire 12A1, the station requirement network 85A1 includes four series-connected component networks 8689, each of the split potentiometer or bridge type and each having its own supply source.

The network 86 includes slidewire 90 whose contact 91 is manually set by basepoint setter 15A1 to the desired basepoint (B; Equation 2) of station A1 and a slidewire 92 whose contact 93 is adjustably positioned by actuator 14A1 in accordance with the actual generation (G; Equation 2) of station A1. Thus, the output voltage of network 86 corresponds with the difference between the basepoint setting of station A1 and its actual generation [BG); Equation 2].

The component network 88 includes the slidewire 94 whose contact 95 is manually preset to correspond with normal system frequency; a slidewire 96 whose contact 97 is adjustably positioned, as by frequency-meter 47,

in accordance with actual system frequency; and a slidewire 98 whose contact 99 is manually preset in accordance with the agreed frequency-bias of the area (L,

Equation 2). Thus, the output voltage of network 88 as appearing between contacts 95, 97 corresponds with the difference (AF; Equation 2) between the normal systerm frequency and the actual system frequency multiplied by the area frequency-bias setting.

The slidewire 84 connected across the output terminals of frequency-bias network 88 has a contact 100 manually set to the same percentage (P; Equation 2) as the stationparticipation slidewire 12A1. Thus, the output of network 17A1 as appearing between contact 100 of slidewire 84 and contact 95 of network 88 is the complete percent area frequency bias factor The component network 89 of computer network 85A1 includes slidewire 102 whose contact 103 is manually preset to correspond with normal system frequency; a slidewire 104 whose contact 105 is positioned in accordance with actual system frequency; and a slidewire 106 whose contact 107 is manually preset in accordance with the desired frequency-bias for station A1 (K; Equation 2). Thus, the output voltage of network 89 corresponds with the difference between normal system frequency and actual system frequency multiplied by the station frequency-bias setting: i. e., the output voltage of network 89, corresponding to device 16A1 of Fig. 1, is the complete station frequency-bias factor (AFK; Equation 2).

The resultant of the algebraic summation of the voltage Equation 2 across the selected percentage of participation slidewire 12A1, and the output voltages of networks 86, 89, 17A1, is automatically balanced by responsive device 13A1 against the output voltage of network 87. This rebalancing network 87 includes fixed resistors 108, 108 and slidewire 109 whose contact 110 is adjustable by responsive device 13A1 to balance the computer network 85A1.

With the network 85A1 in balance, the positions of contact 110 and the exhibiting element 111 movable therewith each corresponds with the generation requirement for station A (AG; Equation 2) taking into account the novel station frequency-bias and the percent area frequency-bias factors.

Because of introduction of these frequency-bias factors in computer network 85A1, any change in generation of station A1, due to response of its unit governors to system-frequency changes, does not appear as an uncompensated factor in the computation of the station requirement and therefore does not demand unnecessary or undesired control action. This is particularly significant for responses to frequency changes resulting from load or generation changes in remote areas and is also significant for local load or generation changes when the generating capacity of the local area is a substantial percentage of the generating capacity of the entire distribution network.

The responsive device 13A1 may also be utilized to control a telemetric transmitter 112(A1) for transmission of a station-requirement signal to station A1. A suitable transmitter arrangement is shown in Phillips Patent 2,754,429. Thus, at station A1, as Well as at each of the other stations of area A, the station-requirement signal may be utilized, as now described, to control the generation of individual units of that station.

At station Al, the telemetric receiver 113(A1) (Fig. 2B) adjusts the contact 115 of slidewire 114 of network 19 so that the output voltage of this network corresponds in sense and magnitude with the requirement of station A1 (AG; Equation 4) as computed by network 85A1 (Fig. 2A) at the load-dispatchers office.

Network 117 (A1), which includes network 19 as one of its components, also includes network 20 whose output voltage as now explained is representative of station regulation. Network 20, like network 19, is a split potentiometer or bridge having fixed resistors and a slidewire 119 whose contact 120 is adjusted to correspond with the computed difference betweenthe summation of the basepoint settings of units 1A1-3A1 of station A1 and the summation of the actual generations of those units.

For automaticadjustment of contact 120, it may be actuated by the rebalancing device 121 of computer network 122A1 which includes a series of network pairs 123, 124 in number corresponding with the generating units of station A1. Each network 123 includes a slidewire 125 whose adjustable contact 126 is manually preset by unit-basepoint setter to correspond with the desired basepoint of the corresponding generating unit. Each network 124 includes a slidewire 127 whose contact 128 is positioned as by wattmeter 129 in accordance with the actual generation of the corresponding generating unit. Thus, the total output of the pairs of networks 123, 124 is the algebraic summation of the unit basepoint settings and the actual unit generations, i. e., station regulation.

The network 130 for rebalancing the resultant of the outputs of pairs of networks 123, 124 includes fixed resistors 131, 131 and a slidewire 132 whose contact 133 is adjustable by the unbalance responsive device 121. Since contact 120 of slidewire 119 of network 20 is also adjustable by responsive device 121, the output of network 20 corresponds with the station regulation (N; Equation 4).

The outputs of networks 19, 20 are combined in computer network 117A1 to effect flow through the unitparticipation slidewires 21(1A1)-21(3A1) in number corresponding with the units of station A1, of a current Whose sense and magnitude corresponds with the algebraic sum of the station requirement and the station regulations E(N+AG); Equation 4]. By manual adjustment of contacts 135 of the unit-participation slidewires, preselected percentages (P'; Equation 4) of this reference signal are allocated to the computer networks 27 (1A1)-27 (3A1) of the different units.

These computer networks utilize the preselected percentages of the reference signal together with other signals below identified to determine the respective unit requirements and to produce signals for control of their respective generations. The unit requirement network 27 (1A1) for unit 1A1 of station A1 is shown in Fig. 2B and now described. Similar networks 27(2A1), 27 (3A1), not shown, are used for the other units of station A1.

In adidtion to unit-participation slidewire 21(1'A1), the unit requirement network 27 1A1) includes four series-connected networks 137-140 each having its own supply source. The network 137 includes a slidewire 141 whose contact 142 is manually set by the basepoint setter 24(1A1) to the desired basepoint (13'; Equation 4) for the unit 1A1 and a slidewire 143 whose contact 144 is variably positioned by actuator 23(1A1) in accordance with the actual generation of unit 1A1 (6; Equation 4). The output of component network 137 therefore corresponds with the difference between the actual generation of unit 1A1 and its required generation [(B'-G); Equation 4].

The component network 139 includes a slidewire 145 whose contact 146 is manually preset to correspond with normal system frequency; a slidewire 147 whose contact 143 is positioned in accordance with actual system frequency, and a slidewire 149 whose contact 150 is manually preset in accordance with the station frequency bias (K; Equation 4). Thus, the output voltage of network 139 as appearing between output contacts 146, 148 corresponds to frequency deviation (AF; Equation 4) multiplied by the station bia setting. The slidewire 151 connected across the output terminals 146, 148 of network 139 has a contact 152 manually set to the same percentage (P'; Equation 4) as the unit-participation slidewire 21(1A1). Thus the output of network 26(1A1) as appearing between contact 152 of slidewire 151 and contact 146 of network 139 is the complete percent station frequency-bias factor 'K E 4 [AF( quanon The component network 149 includes slidewire 153 whose contact 154 is manually preset to correspond with the normal system frequency; a slidewire 155 whose contact 156 is positioned in accordance with actual system frequency; and a slidewire 157 whose contact 158 is manually preset in accordance with the desired frequency bias for unit 1A1 (K; Equation 4). Thus, the output voltage of network 140 corresponds with the deviation from normal frequency multiplied by the unit frequency bias setting (AFK; Equation 4).

The resultant of the algebraic summation of the output voltage of unit-participation slidewire 21(1A1), and the output voltages of networks 137, 1 30, 26(1A1) is automatically balanced by responsive device 22(1A1) against the output voltage of rebalancing network 138. The rebalancing network 138 includes fixed resistors and slidewire whose contact 160 is adjustable by responsive device 22(1A1) to rebalance the computer network 27 1A1).

With network 27(1A1) in balance, the positions of contact 160 of exhibiting element 161 movable therewith each corresponds with the generation requirement for unit 1A1 (AG; Equation 4) taking into account the novel unit and percent station frequency-bias factors. The rebalancing adjustment of computer network 27( 1A1) is utilized to vary the input to the generating unit 1A1 to return its unit requirement (AG') to Zero.

Specifically, the rebalancing device 22(1A1) is-coupied to contact 163 of slidewire 162 of input network 164 for the controller 28 of governor motor 165. In accordance with the sense of the input to controller 28, which may be of the type discolsed in Davis Patent 2,666,170, the motor 165 operates in one direction or the other to change the setting of speed-governor 178 until the controller is restored to balance by adjustment of rebalancing slidewire 166. The controller 28, as in the aforesaid Davis patent may provide proportional, rate, and reset actions. The change in governor setting effected by controller 23 results in change in setting of valve 167 which controls the supply of motor fluid to the prime mover or turbine 168 of generator 169 of unit 1A1. This action continues until AG is reduced tozero.

The other units of station A1 are similarly controlled. The total generation of the units of station A1 as summated by wattmeter 129All is transmitted to the loaddispatchers oflice as by a telemetering link including transmitter 170A1 at the station and receiver 78(A1) at the load-dispatchers office (Fig. 2A) for there positioning the contacts 77 and 93 of the corresponding slidewires 76 and 92 as abovodescribed.

Starting with all unit requirements at zero, then upon occurrence of an area requirement, each of the units of the sustained-response stations A1-A3 will respond to change its generation in sense to correct the deviation from schedule and will continue to change its generation until, but only until, it has assumed its proportionate share of the generation change required of its station.

Normally, the settings of the unit-participation setters forv station A1 add to 100% so that the station requirement (AG) which is the algebraic summation of the unit requirements, becomes zero when the unit controls have all acted to return their respective unit requirements AG to zero. If the settings of the station-participation setters for the sustained response stations All-A3 add to 100%, as is normal practice, the area requirement, which is the algebraic summation of the station requirements, becomes zero when all the station requirements become zero. When all unit requirements have been returned to zero, the total generation change of the area is of the correct magnitude so that its effect ontie-line power flow and system frequency, as sensed by the area-requirement computing circuit, has returned the area-requirement to zero.

If area-assist is desired from station A4, the switches 20A, 29B at the load dispatchers office (Fig. 2A) are closed so that upon occurrence of an area-requirement Raise or Lower pulses are supplied to station A4 (Fig.

13 213) from controller 30A (Fig. 2A). In the form scheinatically shown, the master controller 30A comprises a continuously rotating drum 170 having axially spaced contacts 171, 172 selectively engageable by contact 61 upon displacement thereof from its neutral position by responsive device 38. Preferably, the areas of contacts 171, 172 progressively increase toward opposite ends of drum 170 so that the Raise or Lower pulses produced by the master controller progressively increase in duration for increasing displacement of contact 61 from its neutral position.

The Raise or Lower pulses, as transmitted to station A4 by a telemetering link including transmitter 174 (Fig.

2A) and receiver 175 (Fig. 2B), are respectively utilized periodically to close one or the other of relay switches 176, 177 which control the energization and direction of rotation of governor motor 179. The resulting change in setting of speed-governor 183 results in change of position of valve 180 which controls the supply of motor fluid to prime mover 181 of generator 182 of area-assist unit 1A4.

The other units of area-assist station A4 may be similarly controlled.

Thus, so long as an area requirement exists, the generation of area-assist unit 1A4 is changed in corrective sense within unit-generation limits established by upper and lower limit switches 184, 185 actuated by wattmeter 129(1A4). The total generation of the area-assist station A4 is transmitted to the load-dispatchers office by means including the station wattmeter 129A4, the tele- -metering transmitter 170A4 and the receiver 78A4, Fig.

2A. Contact 77 of the corresponding station-generation slidewire of computer network 70A is positioned by the receiver 78A4. The contact 75 of the corresponding station basepoint slidewire 74 of computer network 70A is manually set by the setter A4 to a position corresponding with the generation this station is to supply when not providing area-assist action.

Any difference between the positions of these slidewires for station A4 represents the accumulated area-assist action of that station and is introduced as a component of the area-regulation in computer network 65A by its effect on the position of slidewire 67. Thus, any generation changes by the area-assist station A4 above or below the basepoint setting of that station are eventually absorbed by the sustained response units of station A1-A3 ,as their individual unit requirements are returned to zero by the control action above discussed. During this period and with no concurrent additional load changes in the area, there exists a temporary mismatch between total actual generation and the total required generation of the area. This appears as an area requirement of reverse sense which is effective to return the assist station to its basepoint but has no efiect on the control of the sustainedresponse stations because during this period the reference signal in network 65A remains constant.

The advantages of introducing generation source frequency-bias factors for control of sustained-response stations has been shown in discussion of Figs. 1, 2A, 218. There will now be discussed the advantages of introducing such frequency-bias factors for control of area-assist sources.

In the area-assist action of Figs. 1, 2A, 2B characterized by continuance of area-assist control action until area requirement is returned to zero, the distribution of the aggregate assist generation is random among the assist sources and the assist generation is not removed from the assisting sources until or unless an area-requirement in the opposite direction occurs or is created.

As will be shown in discussion of Figs. 3, 4A, 48, 9A the introduction of the source frequency-bias factors in association with individual source controllers having individual output feedback, makes it possible to assign to each of the area-assist generation sources a predetermined relationship between the existing area requirement, fre- 14 quency, and the generationof that source. That relationship is of such nature that the source is controlled to participate in preset manner in area-assist for local load changes and insures that the individual source controller shall refrain from taking action when there are sourcegoverning responses to remote load changes.

For an understanding of the considerations involved in attaining an area-assist action of such nature, reference is made to the curves of Fig. 9A.

The individual source controllers are to act to produce the source generation defined by these curves for any prevailing value of system frequency and area requirement. The curves Fl, Fn, F2 illustrate an assigned predetermined relationship between the generation of an area-assist source, the area requirement and system frequency. When the system frequency is normal, the relationship then maintained between source generation and area requirement is exemplified by curve Fn: for zero area requirement, the source generation is Gn, the preset base-point about which the area-assist action-occurs; for a plus or minus area requirement resulting from a local load change, there is a corresponding definite increase or decrease respectively of source generation in amount depending upon the preset slope of curve Fn. Such increase or decrease is the extent of the area-assist action from that source for a local load change having inappreciable trol action upon occurrence of a remote load change first without and then with the source bias-factors. Assume that a remote load change causes the frequency-decrease AF and that the area-assist source controller operates to maintain characteristic Fn only, i. e., no source bias factors. Since the load change is remote, the area requirea remote load drop, the frequency-increase AF results in decreased generation to G1. Point Y does not fall on curve Fn with consequentcontrol action opposing the governing action.

Now for the same remote load changes with accompanying frequency decrease or increase AF, it will be assumed that the area-assist controller operates in accordance with the family of curves exemplified by curves F1, Fri, F2, i. e., the source bias factors effective. As before, the source generation increases to G2 or decreases to Gl while area requirement remains on zero. With curves F2 and F1 displaced to pass through points X and Y for the deviation AF, i. e., displacements on the generation coordinate equal to G2Gn and Gn-Gl for the frequency change AF, the source controller is inactive and does not oppose the governing action. Such ,displacement to match the characteristic of the individual controller to the natural governing characteristic of the controlled source is accomplished by setting the source frequency-bias factor to be equal to the natural governing characteristic.

[The computation of required area assist generation (AGa) for a station based on the relationship shown in 

